A product 10 made from an extruded sheet or web of material 42 having a non-linear cross-section, and the process of making the product 10 is provided. The extruded web or extrudate 42 is plastically deformed in selected areas and then folded. When folded into the appropriate shape, the extrudate 42 is formed into a product 10 having a plurality of cells 14. Optionally, the cells 14a can include one or more openings 34a, allowing access to an interior of the cell 14a and reducing the weight of the product 10a.
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1. A process of making a sandwich-like product comprising:
extruding a web of material having a generally non-planar profile comprising continuous corrugations with continuous flattened peaks and flattened valleys joined by connecting portions extending in the direction of travel of the web;
interrupting the continuous corrugations of the extruded web using movable tools on opposite sides of the extruded web to create non-perforated transversely extending rectangular flats to create a plastically deformed web;
folding the plastically deformed web along transversely extending fold lines along the edges of the flats to create a honeycomb core comprising a plurality of cells arranged in rows, each of the cells having a top and a bottom, the top and bottom each being in the shape of a polygon;
applying generally planar outer skins to the tops and bottoms of the cells of the honeycomb core to create a multi-layered web; and
cutting the multi-layered web.
7. A process of making a product comprising:
extruding a web of material such that the extruded web has a generally non-linear cross-section comprising continuous corrugations with continuous flattened peaks and flattened valleys joined by connecting portions extending in the direction of travel of the web;
flattening rectangular, non-perforated transversely extending areas of the extruded web using movable tools on opposite sides of the extruded web to create non-perforated, transversely extending flattened areas between corrugated sections, every other one of the flattened areas being co-planar with the flattened peaks of the extruded web;
folding the extruded web along transversely extending fold lines located generally on the edges of the flattened areas such that the corrugated sections become sidewalls of a honeycomb core comprising a plurality of identical cells arranged in rows, the corrugated sections of the extruded web becoming the sidewalls of the cells and the flattened areas become tops and bottoms of the cells;
applying generally planar outer skins to the tops and bottoms of the cells of the honeycomb core to create a multi-layered web; and
cutting the multi-layered web.
16. A process of making a sandwich-like product comprising:
extruding a web of material having a generally non-planar profile comprising continuous corrugations with continuous flattened peaks and flattened valleys joined by connecting portions extending in the direction of travel of the web;
flattening selected areas of the extruded web using at least one movable tool to interrupt the continuous corrugations to create a plurality of corrugated regions each comprising a plurality of corrugations extending in a first direction generally parallel to the direction of travel of the extruded web and a plurality of continuous, transversely extending, non-perforated rectangular flats each extending in a second direction perpendicular to the first direction;
folding the web along fold lines extending in the second direction to create a honeycomb core, the fold lines being along the edges of the flattened areas, the honeycomb core comprising a plurality of cells arranged in rows, each of the cells having sidewalls made from the interrupted corrugations of the extruded web, a top in the shape of a polygon and a bottom in the shape of a polygon;
applying outer skins to the tops and the bottoms of the honeycomb core to create a multi-layered web; and
cutting the multi-layered web.
13. A process of making a sandwich-like product comprising:
extruding a web of material such that the extruded web has a generally non-linear cross-section comprising continuous corrugations having continuous flattened peaks and continuous flattened valleys joined by continuous connecting portions extending in a longitudinal direction;
interrupting the continuous corrugations of the extruded web using movable tools on opposite sides of the extruded web to create spaced non-perforated, transversely extending flats to create a plastically deformed web, the flats being generally co-planar with either the flattened peaks or the flattened valleys of the continuous corrugations where the flats alternate between being generally co-planar with a flattened peak and being generally co-planar with a flattened valley;
folding the plastically deformed web along transversely extending fold lines along the edges of the flats to create a honeycomb core comprising a plurality of cells arranged in rows, each of the cells having a top and a bottom, the top and bottom each being in the shape of a polygon, one of the top and bottom being single ply and the other of the top and bottom being double ply;
applying outer skins to the tops and bottoms of the cells of the honeycomb core to create a multi-layered web; and
cutting the multi-layered web.
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This application is a continuation of U.S. patent application Ser. No. 11/566,973, filed Dec. 5, 2006 entitled “Folded Product Made From Extruded Profile and Method of Making Same”, which is fully incorporated herein.
This invention relates generally to a product for structural, packaging, and other applications and the process of making the product.
In the aerospace industry, honeycomb products have been used as a core component for sandwich panels and boards that are resistant to buckling and bending. These honeycomb products each comprise a plurality of cells, which in cross-section have a generally hexagonal shape. Such products may be fabricated from aluminum, fiber paper or plastic, among other materials. A sandwich structure may be prepared having two cover layers or skins which are welded, adhesively bonded or otherwise secured to the honeycomb product to create a multi-layered or multi-laminate material. Interest expressed in other industrial sectors concerning the use of light weight sandwich structures is continually growing, due at least in part to the realization of its high strength properties while maintaining a relatively low structural weight per volume of product.
A multi-layered or multi-laminate material having a honeycomb product as the core thereof may be used in the packaging industry. However, in automobile part packaging and comparable markets, such a product must compete with corrugated paperboard or corrugated plastic or like materials which may be produced quickly and relatively inexpensively.
U.S. Pat. No. 6,183,836 discloses a honeycomb core for use in a sandwich material in which the material of the honeycomb core is cut and then folded to create a plurality of hexagonal cells. Due to the cuts in the sheet prior to folding the sheet, the resultant cells may be weaker than desired.
A process for producing a folded honeycomb core for use in sandwich materials from a continuous uncut web is disclosed in U.S. Pat. No. 6,726,974. U.S. Pat. No. 6,800,351 discloses another process for producing a folded honeycomb core which includes scoring a corrugated material before rotating interconnected corrugated strips. The honeycomb core resulting from using either of these methods may have material which adds to the weight of the honeycomb core but may not significantly improve the strength of the honeycomb core.
Accordingly, there is a need for a product which may be used alone or in a multi-layered material, and which has a favorable strength-to-weight ratio.
There is further a need for a process for manufacturing a product such as a honeycomb product for use alone or in a multi-layered material which is less expensive and may be produced in higher quantities than heretofore known processes.
These and other objectives of the invention have been attained in a process for producing a product, such as a honeycomb product, for use alone or in a sandwich-like product. The process includes extruding a web of material which has a non-planar profile, i.e., has a non-linear cross-section, plastically deforming or treating portions of such web, and then folding the treated web to produce the product. Other fabrication operations may optionally be included in the process. The process of preparing a web of material suitable for further fabrication into a product is rendered efficient in part by producing an extrudate having a non-linear cross-section. For purposes of this document, linear shall be defined as a single straight continuous line, the shortest distance between two points. Each of the extrudates or extruded webs illustrated herein has a non-planar profile and has a non-linear cross-section. Shapes of other webs of material not shown are intended to be included in such a definition.
The extrudate displays a non-linear cross-sectional configuration upon exiting the extruder head. This cross-section may assume any of a variety of shapes. A relatively simple shape would be that of a continuous sine wave. Another example is corrugated plastic. More complex shapes can include interrupted sine wave sections connected by straight lines, one or more polygons connected by straight lines, nested polygons, and the like, as needed or desired in connection with ultimately preparing the core structure of interest.
Representative product, like a honeycomb product, can be produced using a variety of starting materials capable of being processed through an extruder, including various plastic compositions, in an efficient manner to produce a product having good strength-to-weight properties. The product may be used alone, or may be incorporated as a part of a multi-layered sandwich-like material to produce, for example, panels or sheets used in structural applications. More broadly, the products of the present invention may be used in any desired environment or industry. For example, product may be produced under conditions which generate a material having a high surface area. The material may then be further treated to produce a product having surface activity, which could be used, for example, in catalytic applications.
According to one aspect of this invention, a process of making a product comprises extruding a web of material having a predetermined or desired width or transverse dimension, the extruded web having a generally non-linear cross-section; plastically deforming, such as flattening areas of the extruded web; and folding the web.
As defined herein, the term “web” encompasses material processed in extrusion equipment intended to accept the specific material introduced into that equipment, and issuing or exiting from an extruder head. The extrudate has a non-linear cross-section. In one aspect of the present invention, a plurality of openings may be introduced into the extruded web. These openings can be introduced by stamping the material, but may also include processing of the extruded web by one or more tools to thereby form the openings. As used herein, a tool is intended to encompass any device, or energy flowing from that device, which is used to desirably alter the physical appearance of the web. Thus, by way of example and not by limitation, a tool for the purpose of forming a plurality of openings in the extruded web can include a laser cutter, one or more rotating cutting blades, a perforating or slitting machine, and the like.
The process of plastically deforming or flattening selected areas of the extruded web can comprise contacting the extruded web with an element which may be heated. Alternatively, selected areas of the extruded web can be flattened by a tool applying pressure, heat, or a combination of pressure and heat, in one or more selected areas. The process of flattening may alternatively precede the introduction of openings into the extruded web, may follow the introduction of openings into the extruded web, or the two processes may occur substantially simultaneously.
One type of non-linear cross-section shape which the extruded web may display is a generally corrugated shape with flattened peaks and flattened valleys along the transverse dimension of the extruded web. Further, the extruded web is folded along transversely extending fold lines during the folding step. One or more individual cells can be formed as a result of the folding step, for example, where a section of the extrudate is oriented at 90° from its original position by the folding operation.
The process of making a product, like a honeycomb product, may also encompass extruding a web having a generally non-linear cross-section which, in addition, forms a plurality of substantially closed channels. Small openings in one or more channels, up to all channels in the extruded web, may be introduced to facilitate introduction of a cooling medium to the extrudate, as required based on the particular material utilized to produce the web and the complexity and wall thickness of the web, or portions thereof. The openings may extend in a continuous fashion along the entire length of the channel, or openings may be intermittently introduced along the channel length. Further processing with one or more tools can be effected on this type of extruded web in a manner similar to that discussed above to alter the appearance of the extruded web, by cutting, flattening, folding and the like.
The product of this invention can also comprise an extruded web having a non-linear cross-section formed into a plurality of similar cells arranged in rows, wherein at least some of the rows of cells are being made of two row walls, each of the row walls having alternating planar and non-planar regions, the planar regions of the adjacent row walls being joined together and non-planar regions of the adjacent row walls defining side walls of the cells, wherein each of the cells have side walls, a top and a bottom. This product can be characterized by at least one opening created by at least one tool in at least some of its cells.
In a further aspect, the product has at least some openings in lateral side walls of at least some of the cells. At least some of the cell openings can be of a pre-defined size, or of a pre-defined shape, or both a pre-defined size and shape.
The product made from extruded web material can be produced by manipulating the web material into a plurality of similar cells arranged in rows, at least some of those cells being made of a continuous cell wall, the continuous cell wall may have any desired shape including the shape generally of a ring, wherein the cells are oriented substantially 90° to the longitudinal dimension of the extrusion web material.
Another aspect of the invention is a product, such as a honeycomb product, made by the process of extruding a web of material having a transverse dimension, the extruded web having a generally non-linear cross-section; creating a plurality of generally planar areas in the extruded web; folding the extruded web along edges of the generally planar areas to create a plurality of identical cells arranged in rows, at least some of the rows of cells being made of two row walls, each of the row walls having planar and non-planar regions, the regions of adjacent row walls being joined together, and non-planar regions of adjacent row walls defining side walls of the cells, each of the cells also having a top and bottom. If desired, one may form in at least some of the cells an opening created by at least one tool.
The tops and bottoms of the cells of the honeycomb product described herein may be in the shape of a polygon. More specifically, the honeycomb product may be shaped such that the polygon is a hexagon. In a further aspect of the invention, each of the cells may have an opening allowing access to an interior of the cell.
In another aspect of the invention, where a plurality of openings is formed in the web of material, those openings typically extend completely through the web. The openings may be circular, but may assume one of any number of other shapes, such as oval, hourglass, asymmetric, and the like. The openings optionally correspond to locations along the web wherein material has been removed to realize good strength-to-weight properties.
Regardless of the method used to create the product, one advantage is that a light weight, strong product may be quickly and easily manufactured in a desired size or height. The product of this invention, which is produced according to the processes described herein, has a good strength-to-weight ratio even without forming openings in the web, and may be made from many different materials quickly and inexpensively. The strength-to-weight ratio may be improved by strategic removal of material from the extruded web at some time in the process of fabricating the product. The product may be used alone, incorporated into a multi-layered sandwich-like material, or used in any other desired manner.
The objectives and features of the present invention will become more readily apparent when the following detailed description of the drawings is taken in conjunction with the accompanying drawings in which:
Referring to
As shown in
In certain applications, such as, for example, when a web of thermoplastic material is heated at some stage in the manufacture of the honeycomb product 10, the planar regions 22 of adjacent row walls 20 may be bonded, welded or secured to each other without any additional material. Alternatively, adhesive or another bonding agent may be used to secure adjacent row walls 20 together to complete the rows 12 of cells 14. The non-planar regions 24 of adjacent row walls 20 are spaced apart and define the shape or configuration of the cells 14 after the manufacturing process has been completed. Outermost portions or sides 74 of adjacent cells 14 in different rows 12 may contact each other and may be secured to each other in certain applications of this invention.
Although the drawings illustrate each non-planar region 24 of each row wall 20 having a cross-sectional configuration of a half-hexagon, the non-planar regions of the row walls may have any desired cross-sectional configuration, such as, for example, a curved or arcuate or sinuous cross-sectional configuration. The creation of the side walls or sides 74, 76 of the cells 14 is described in more detail below. Depending upon the application, the cells 14 may be any desired shape or size.
As best illustrated in
In the illustrated embodiment, each cell top 28 and bottom 30 is a polygon and, more particularly, a hexagon. However, if the non-planar regions of the row walls were in the shape of half a cylinder, then the tops and bottoms of the cells would be circular or oval, and the cells would have a cylindrical interior.
In
The extruded web 42 has a generally non-linear cross-section or cross-sectional configuration. In cross-section, the extruded web 42 has a generally corrugated configuration or shape, including a plurality of flattened peaks 48 and a plurality of flattened valleys 50 joined together by connecting portions 52. Each of the flattened peaks 48, flattened valleys 50 and connecting portions 52 are longitudinally extending, as shown in
Although tool 60 is illustrated as comprising three bars 64 joined together with connectors 66 (only one being shown for clarity) and tool 61 is illustrated as comprising two bars 64 joined together with connectors 65 (only one being shown for clarity), respectively, these tools 60, 61 may comprise any number of bars of any desired size or configuration joined together or not. Although two tools are illustrated, any number of tools of any desired type or configuration may be used. Again, the term tool is not intended to be limiting and may include any tool known in the art.
During the step of plastically deforming at least selected portions of the extruded web 42, the bars 64 of the tools 60, 61 may be chilled, at ambient temperature, or heated by any desired method to facilitate processing. Such heating is illustrated schematically by arrows 38. This heating step is optional and may be used in certain applications only. In other applications, it may be omitted partially or entirely. Although it is shown schematically after the flats 54, 56 have been created in the extruded web 42, this heating step may occur any time during this manufacturing process.
Due to the creation of the flattened areas or flats 54, 56, each corrugation 46 may have an end portion 69 which extends between a peak 48 and a valley 50. These end portions 69 are illustrated as each being in the shape of a trapezoid, but may be other shapes, depending upon the shape of the corrugations.
As best illustrated in
As shown in
As best illustrated in
As shown in
The last step in the process is to cut the extruded web 42 at any desired location.
The extruded web 42a is then treated as described above and illustrated in
As best illustrated in
Although a punch press is illustrated, any other tool, such as a laser cutter, may be used to create the openings 34a through any portion of the plastically deformed portion 58a of the extruded web 42a to lighten the extruded web 42a so that when this portion of the web 42a is formed into a honeycomb product 10a, the resultant honeycomb product 10a has a relatively high strength-to-weight ratio due, at least in part, to the removal of such material during the process of manufacturing the honeycomb product.
Although the tool 82 is illustrated beneath the extruded web 42a, tool 82 may be located above the extruded web 42a or at any desired location. More than one tool may be used if desired.
As shown in
As shown in
The last step in the process is to cut the extruded web 42a at any desired location.
Although one configuration of tool 60b (and 61b) is illustrated comprising bars 64b joined by connectors 66b (and 65b), any other configuration or type of tool may be used to plastically deform extruded portions of web 42b. Such tools may simultaneously create openings 34b through any portion of the extruded web to lighten the extruded web 42b so that when this portion of the web 42b is folded to create honeycomb product 10b, the resultant honeycomb product 10b has a relatively high strength-to-weight ratio due, at least in part, to the removal of such material during the process of manufacturing the honeycomb product 10b.
Although the tools 60b and 61b are illustrated respectively above and below extruded web 42b, the orientation of tools 60b and 61b may be reversed, or at any other desired location, such as one after the other in a staggered format. Any number of tools 60b, 61b may be used if desired.
During the step of plastically deforming at least selected portions of the extruded web 42b, the bars 64b of the tools 60b, 61b may be chilled, at ambient temperature, or heated by any desired method to facilitate processing. Such heating is illustrated schematically by arrows 38b. This heating step is optional and may be used in certain applications only. In other applications, it may be omitted partially or entirely. This heating step may occur any time during this manufacturing process.
As shown in
The last step in the process is to cut the plastically deformed extruded web 58b at any desired location.
As noted above, the cross-section of the extruded web can assume any number of shapes.
The temperature needed to process a plasticated material through an extruder and out an extruder head, such as 41′ in
To improve access, one or more access openings 101 may be introduced into one or more longitudinally extending channels 44 of the web 42′. Creation of an access opening 101 into a channel forms a modified channel 44′ described herein as being substantially closed. See
As shown in
Additional portions 124a-d shown in
As seen in
One advantage of the present invention is the ability to extrude a product with reduced weight or density compared to the weight or density of a single solid sheet or web of the same material of the same dimensions. Due to the presence of holes, flutes or channels 136 in the extrudate 42″, as best shown in
Although tool 140 is illustrated as comprising six deforming members 144 joined together with connectors 146 (only one being shown for clarity), and tool 142 is illustrated as comprising five deforming members 148 joined together with connectors 150 (only one being shown for clarity), respectively, these tools 140, 142 may comprise any number of deforming members of any desired size or configuration, joined together or not. Although two movable tools are illustrated, any number of tools of any desired type or configuration may be used. Again, the term tool is not intended to be limiting and may include any tool known in the art.
During the step of plastically deforming at least selected portions of the extruded web 42″, the deforming members 144, 148 of tools 140, 142, respectively, may be chilled, at ambient temperature, or heated by any desired method to facilitate processing. Such heating is illustrated schematically by arrows 152. This heating step is optional and may be used in certain applications only. In other applications, it may be omitted partially or entirely. Although it is shown schematically during the creation of the plastic deformed areas 138 of the extruded web 42″ using tools 140, 142, this heating step may occur any time during this manufacturing process.
As shown in
Another step in the process may be to cut the extruded web 42″ at any desired location.
This method comprises plastically deforming or flattening at least selected portions or areas 162, 164 of the extruded web 42″ to create a plastically deformed extruded web 166. This plastic deformation may include using movable tools 168, 170, such as shown in
Although tool 168 is illustrated as comprising three bars 174 joined together with connectors 176 (only one being shown for clarity), and tool 170 is illustrated as comprising two bars 174 joined together with connectors 180 (only one being shown for clarity), respectively, these tools 168, 170 may comprise any number of bars of any desired size or configuration joined together or not. Although two tools are illustrated, any number of tools of any desired type or configuration may be used. Again, the term tool is not intended to be limiting and may include any tool known in the art.
During the step of plastically deforming at least selected portions of the extruded web 42″, the bars 174 of the tools 168, 170 may be chilled, at ambient temperature, or heated by any desired method to facilitate processing. Such heating is illustrated schematically by arrows 178. This heating step is optional and may be used in certain applications only. In other applications, it may be omitted partially or entirely. Although it is shown schematically after the flats 162, 164 have been created in the extruded web 42″, this heating step may occur any time during this manufacturing process.
As best illustrated in
As shown in
Another step in the process may be to cut the extruded web 166 at any desired location.
While we have described several preferred embodiments of the present invention, persons skilled in the art will appreciate changes and modifications which may be made without departing from the spirit of the invention. For example, although one configuration of a cell is illustrated and described, the cells of the present invention may be other configurations, such as cylindrical in shape. Therefore, we intend to be limited only by the scope of the following claims and equivalents thereof.
Bradford, Judson A., Nyeboer, Calvin D.
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